Intra-specific leaf trait responses to species richness at two different local scales

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Intra-specific leaf trait responses to species richness at two different local scales. / Davrinche, Andréa; Haider, Sylvia.
in: Basic and Applied Ecology, Jahrgang 55, 01.09.2021, S. 20-32.

Publikation: Beiträge in ZeitschriftenZeitschriftenaufsätzeForschungbegutachtet

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@article{56e3fe16562a40ba93b74df4b653fbb3,
title = "Intra-specific leaf trait responses to species richness at two different local scales",
abstract = "Plant functional traits, especially leaf traits, are accepted proxies for ecosystem properties. Typically, they are measured at the species level, neglecting within-species variation. While there is extensive knowledge about functional trait changes (both within and across species) along abiotic gradients, little is known about biotic influences, in particular at local scales. Here, we used a large biodiversity-ecosystem functioning experiment in subtropical China to investigate intra-specific trait changes of 16 tree species as a response to species richness of the local neighbourhood. We hypothesized that because of positive complementarity effects, species shift their leaf traits towards a more acquisitive growth strategy, when species richness of the local neighbourhood is higher. The trait shift should be most pronounced, when a focal tree's closest neighbour is from a different species, but should still be detectable as a response to species richness of the directly surrounding tree community. Consequently, we expected that trees with a con-specific closest neighbour have the strongest response to species richness of the surrounding tree community, i.e., the steepest increase of acquisitive traits. Our results indicate that species diversity promoted reduced competition and complementarity in resource use at both spatial scales considered. In addition, the closest neighbour had considerably stronger effects than the surrounding tree community. As expected, trees with a con-specific nearest neighbour showed the strongest trait shifts. However, the predicted positive effect of local hetero-specificity disappeared at the highest diversity levels of the surrounding tree community, potentially resulting from a higher probability to meet a strong competitor in a diverse environment. Our findings show that leaf traits within the same species vary not only in response to changing abiotic conditions, but also in response to local species richness. This highlights the benefit of including within-species trait variation when analysing relationships between plant functional traits and ecosystem functions.",
keywords = "Biology, Trait-based ecolog, Plant functional traits, ntraspecific trait variability, BEF-China, Diversity effects, Complementarity, Subtropics",
author = "Andr{\'e}a Davrinche and Sylvia Haider",
note = "Publisher Copyright: {\textcopyright} 2021 Gesellschaft f{\"u}r {\"O}kologie",
year = "2021",
month = sep,
day = "1",
doi = "10.1016/j.baae.2021.04.011",
language = "English",
volume = "55",
pages = "20--32",
journal = "Basic and Applied Ecology",
issn = "1439-1791",
publisher = "Elsevier B.V.",

}

RIS

TY - JOUR

T1 - Intra-specific leaf trait responses to species richness at two different local scales

AU - Davrinche, Andréa

AU - Haider, Sylvia

N1 - Publisher Copyright: © 2021 Gesellschaft für Ökologie

PY - 2021/9/1

Y1 - 2021/9/1

N2 - Plant functional traits, especially leaf traits, are accepted proxies for ecosystem properties. Typically, they are measured at the species level, neglecting within-species variation. While there is extensive knowledge about functional trait changes (both within and across species) along abiotic gradients, little is known about biotic influences, in particular at local scales. Here, we used a large biodiversity-ecosystem functioning experiment in subtropical China to investigate intra-specific trait changes of 16 tree species as a response to species richness of the local neighbourhood. We hypothesized that because of positive complementarity effects, species shift their leaf traits towards a more acquisitive growth strategy, when species richness of the local neighbourhood is higher. The trait shift should be most pronounced, when a focal tree's closest neighbour is from a different species, but should still be detectable as a response to species richness of the directly surrounding tree community. Consequently, we expected that trees with a con-specific closest neighbour have the strongest response to species richness of the surrounding tree community, i.e., the steepest increase of acquisitive traits. Our results indicate that species diversity promoted reduced competition and complementarity in resource use at both spatial scales considered. In addition, the closest neighbour had considerably stronger effects than the surrounding tree community. As expected, trees with a con-specific nearest neighbour showed the strongest trait shifts. However, the predicted positive effect of local hetero-specificity disappeared at the highest diversity levels of the surrounding tree community, potentially resulting from a higher probability to meet a strong competitor in a diverse environment. Our findings show that leaf traits within the same species vary not only in response to changing abiotic conditions, but also in response to local species richness. This highlights the benefit of including within-species trait variation when analysing relationships between plant functional traits and ecosystem functions.

AB - Plant functional traits, especially leaf traits, are accepted proxies for ecosystem properties. Typically, they are measured at the species level, neglecting within-species variation. While there is extensive knowledge about functional trait changes (both within and across species) along abiotic gradients, little is known about biotic influences, in particular at local scales. Here, we used a large biodiversity-ecosystem functioning experiment in subtropical China to investigate intra-specific trait changes of 16 tree species as a response to species richness of the local neighbourhood. We hypothesized that because of positive complementarity effects, species shift their leaf traits towards a more acquisitive growth strategy, when species richness of the local neighbourhood is higher. The trait shift should be most pronounced, when a focal tree's closest neighbour is from a different species, but should still be detectable as a response to species richness of the directly surrounding tree community. Consequently, we expected that trees with a con-specific closest neighbour have the strongest response to species richness of the surrounding tree community, i.e., the steepest increase of acquisitive traits. Our results indicate that species diversity promoted reduced competition and complementarity in resource use at both spatial scales considered. In addition, the closest neighbour had considerably stronger effects than the surrounding tree community. As expected, trees with a con-specific nearest neighbour showed the strongest trait shifts. However, the predicted positive effect of local hetero-specificity disappeared at the highest diversity levels of the surrounding tree community, potentially resulting from a higher probability to meet a strong competitor in a diverse environment. Our findings show that leaf traits within the same species vary not only in response to changing abiotic conditions, but also in response to local species richness. This highlights the benefit of including within-species trait variation when analysing relationships between plant functional traits and ecosystem functions.

KW - Biology

KW - Trait-based ecolog

KW - Plant functional traits

KW - ntraspecific trait variability

KW - BEF-China

KW - Diversity effects

KW - Complementarity

KW - Subtropics

UR - http://www.scopus.com/inward/record.url?scp=85108564944&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/fe7690d3-548b-36c9-ac11-7dfbbc91a434/

U2 - 10.1016/j.baae.2021.04.011

DO - 10.1016/j.baae.2021.04.011

M3 - Journal articles

AN - SCOPUS:85108564944

VL - 55

SP - 20

EP - 32

JO - Basic and Applied Ecology

JF - Basic and Applied Ecology

SN - 1439-1791

ER -

DOI